RU2600554C2 - Guide for elevators or lifts and method for manufacturing said guide - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: guide for lifts comprises a base portion, two boundary edges placed at opposite side ends of base portion and a central protrusion emerging from base portion. Guide further comprises at least one mass-redistribution portion formed in base portion and adapted to lighten base portion at an intermediate part thereof included between central protrusion and at least one boundary edge, and also adapted to make base portion heavy at a localised end part thereof in vicinity of at least one boundary edge. Dimensions in cross-section of guide are selected in following ranges: total height varying from 60 to 80 mm;

and/or width of base portion in range of 60 to 95 mm; and/or remote bulge width varying from 7 to 18 mm; and/or height of remote thickening in range of 30 to 45 mm; and/or height of at least one boundary rib varies from 6 to 12 mm; and/or height of centre of gravity of cross-section relative to base portion in range of 18 to 30 mm; and/or cross-section area within range of 8 to 20 cm². Method of manufacturing includes operations for making guide taking into account said features. Intermediate element provides attachment of guide to wall.

EFFECT: higher strength and reduced material consumption of guide.

12 cl, 4 dwg

Description

The invention relates to a guide for hoists and elevators used, for example, in civil, commercial or industrial fields, as well as to a method for manufacturing such a guide.

It is known that guides for elevators consist of sections having a straight longitudinal axis, mounted sequentially in the guide channels of said elevators; moreover, these guides usually have a T-shaped cross section, in which there is a base, usually located close to the walls of the guide channel and attached to them, and a Central protrusion protruding from the base and protruding into the guide channel.

Guides of a known type are manufactured using various methods that require the use of important and accurate control tools to ensure and maintain high production accuracy (for example, regarding straightness or angular curvature of the main axes of an object); these strict manufacturing requirements are directly related to the uniformity of the elevator sliding, which in turn leads to the normal movement of the elevator without jerking for passengers.

Returning to the geometrical shape of the guides of a known type, one can notice that they are usually equipped with a base having a flat side in cross section (which is usually the side adjacent to the wall of the guide channel) and the opposite side, consisting of two beveled surfaces converging to the central protrusion, and at the same time, forming an increase in thickness in the direction from the side faces of the base to the center.

The central protrusion, in turn, has a variable thickness (still also in cross section) between the proximal portion of smaller thickness, which is usually directly connected to the central portion of the base, and the remote portion of increased thickness.

The guide rail design just described, despite its widespread use, has several disadvantages.

In fact, the guide sections for elevators of a known type do not allow the full use of the mechanical characteristics of the material from which they are made; in other words, the shape of the guides for elevators of a known type generally leads to an excess of mass (and, as a consequence, an excess of material used to make the guide itself), or to the non-optimal use and distribution of internal forces in the guide itself.

In addition, guides for elevators of a known type are attached to the walls of the guide channels with sets of screws and / or intermediate coupling elements that require a rather complicated installation (usually based on the use of a large number of screws and nuts); this increases the assembly time of the elevator installation and its cost.

In light of the aforementioned drawbacks, it is an object of the present invention to provide an elevator guide to overcome the drawbacks mentioned.

In particular, it is an object of the present invention to provide an elevator guide having a higher structural efficiency both in terms of more efficient use of its mechanical strength and in terms of reducing the amount of material (and therefore weight reduction) required for production.

At the same time, the present invention is directed to the development of a method for manufacturing such elevator guides, providing high reproducibility, high production rates and including a sequence of simple operations subject to easy control / task.

In addition, the present invention is directed to the development of an intermediate coupling member that can be placed between the guide and the wall of the guide channel where said guide is installed in a simple, quick and reliable way.

These and other objectives are achieved by using the elevator guide according to the invention, disclosed and claimed hereinafter in the embodiment presented by a non-restrictive example, and illustrated in the accompanying drawings, where:

- figure 1 shows a perspective guide for elevators, according to the invention;

- figure 2 schematically shows a section of a guide according to the invention depicted in figure 1;

- figure 3 shows a perspective intermediate fastener connected to the guide shown in figures 1 and 2;

- Fig. 4 shows a front view of the intermediate fastener depicted in Fig. 3, associated with a guide for elevators of a general type.

As shown in the accompanying drawings, the guide for the hoists according to the invention is generally indicated by the number 1 and comprises a main body 2 extended along a corresponding (generally straight line) main axis 2a; moreover, this main body in cross section contains a base part 3 having a supporting side 3a, which can adjoin the wall when the guide 1 is installed, and the direction-setting side 3b opposite to the supporting side 3a.

As shown hereinafter (and clearly seen in the drawings), the support side 3a, which is expediently made flat, and the direction-setting side 3b, which opposite has a non-flat surface, together form a variable thickness of the base part 3.

It is advisable to perform two boundary ribs 4 located on mutually opposite side faces of the base part 3, and you can also see the presence of a Central protrusion 5, protruding from the direction-determining side 3b; this central protrusion 5 has a proximal base 5a connected to the base portion 3, and a distal bulge 5b connected to the proximal base 5a.

Advantageously, due to the specific shape of the guide 1, at least one mass redistribution portion 6 is performed. This mass element is formed in the base part 3 to facilitate the base part 3; in particular, this mass transfer action is performed in the “intermediate part” of the base part located between the central protrusion 5 and at least one boundary rib 4.

It should also be noted that in the framework of the present invention, the mass redistribution section 6 (which, to achieve the objectives of the present invention, can be performed both as a section in the cross section of which additional material is present and as a section characterized by a smaller amount of material compared to conventional guide sections for elevators of a known type) is also intended to weight the base part 3 in its local terminal part near at least one boundary rib 4.

Due to the excellent shape of the guide obtained by performing the mass reallocation on the guide 1 of said part 6, it is possible to obtain changes in the mechanical / geometric properties of the guide itself, and in particular, it is possible to change both the main moments of inertia of the guide and its so-called “stress center "In order to obtain improved mechanical performance of the material used and, in other words, to allow the use of less composite material to obtain the same mechanical eskih performance.

In addition, the presence of empty space in the recess 6a makes it possible to install additional devices on the guide 1, for example, such as magnetic position sensors (which in guides of a known type should be placed under the so-called "rail"); this allows them to have a better readout and thus increase sensitivity / accuracy with the benefit of elevator performance.

In order to ensure symmetry in the properties, it is advisable that the guide according to the invention had two sections 6 of the redistribution of mass located on mutually opposite (and, as a rule, removed at the same distance) parts relative to the Central protrusion 5.

In more detail, it should be noted that at least one, and preferably both, sections of the redistribution of mass contain facilitating recess 6a, made in the direction-defining side 3b, and a local thickening 6b near the boundary rib 4; in fact, the mass excluded from the intermediate part of the base part is “restored” in parts more distant from the geometric center of the cross section of the guide 1; Thus, the amount of material in the most critical sections of the section is maximized, while at the same time, the moments of inertia are maximized and the total amount of “filled space” required to form the guide itself is optimized.

It should also be noted that due to various possible geometrical configurations that can be imparted to the facilitating recess 6a and / or local thickening 6b, new geometrical shapes of the guide 1 can be defined; in particular, the drawings attached to this description show an example in which the intermediate part and the end part of the base part 3 have a correspondingly constant cross-sectional thickness relative to the main axis 2a (while the guides for elevators of a known type have a base part with a thickness uniformly increasing in the direction from the boundary ribs to the central protrusion).

According to one additional feature of the present invention, at least one connecting portion 7 is also provided, located between the mass redistribution portion 6 and the central protrusion 5; said connecting portion 7 is located between the facilitating recess 6a and said proximal base 5a and preferably has a peak shape and / or pointed configuration in cross section relative to the main axis 2a (it should be noted that such a configuration may result from the formation of the facilitating recess 6a, which usually performed by pressing and / or rolling and / or drawing, after a similar operation was performed for the earlier formation of the near base 5a).

Obviously, depending on the technological requirements of production, the so-called “molding” method can also be performed using other known processes, such as hot rolling.

More precisely speaking about the method of manufacturing the specified guide 1, and the presentation of the method of manufacturing the guide for elevators, elevators, etc. also an object of the present invention, it comprises the following steps:

- first, preforming of the preform is carried out by a predetermined number of coarse processing steps so as to define its main axis 2a and a temporary section;

- then refine the workpiece by a given number of finishing stages (following the rough processing stages); Thus, the finished workpiece acquires a sharper outline of the cross section relative to the main axis 2a (so as to more clearly form, visually distinguishable, at least one base part 3, two boundary ribs 4 and the central protrusion 5).

Advantageously, the method of the present invention further comprises the step of performing mass redistribution in at least the base portion 3; This step is intended to facilitate the base part 3 in its intermediate part between the central protrusion 5 and at least one boundary rib 4, as well as to weight the base part 3 in its local terminal part near the boundary rib 4.

As mentioned above, the steps of preforming a workpiece, finishing it, and performing mass redistribution can be performed by profiling and / or drawing and / or gouging and / or rolling and / or hot rolling (depending on current requirements).

In order to ensure quick, accurate and easy installation of the rail 1 according to the present invention, it is advisable to use an intermediate coupling element that can be mounted between the rail for lifts (such as described and claimed in this application, or another type, if necessary) and the wall.

From a structural point of view, this intermediate connecting element essentially comprises a connecting part 10 for connection with the wall and an active part 11 connected to the connecting part 10 and made with the possibility of activation on the guide for elevators.

Advantageously, the intermediate connecting element (indicated as a whole by the number 100 in the accompanying drawings) further comprises elastic pressing means formed integrally in the connecting part 10 and / or the active part 11; these elastic pressure means are configured to hold the elevator guide in place by means of spring-type reaction forces and / or by direct mechanical interaction, without the use of mechanical pressure of the “indirect” type formed by conventional joints based on the use of nuts, threaded rods and screws.

More specifically, it can be noted that the intermediate bonding element can be made in such a way that the connecting part 10 and the active part 11 are made without breaking by bending and / or profiling a thread-like or ribbon-like element; moreover, this thread-like or ribbon-like element, in turn, can preferably consist of a metal material (which mainly retains elastic properties) to provide the aforementioned necessary mechanical action, including direct pressure.

In more detail, with respect to the element 100, it can be noted that it may comprise at least one docking socket 12 integrally formed in a filamentary or ribbon-like element; moreover, this docking socket 12 is designed to introduce a release tool (for example, a conventional screwdriver), which in turn can be used to engage or disengage the element 100 with the guide 1; in addition, one or more blocking extensions 13 may be integrally formed on the filiform or ribbon-like element.

The blocking extensions 13 are designed to abut at least one boundary rib 4 and / or in the facilitating recess 6a and / or in the local thickening 6b of the guide 1 to hold it in the longitudinal and transverse directions relative to the main axis 2a.

In the framework of the present invention, the docking slot 12 and the blocking extensions 13 preferably consist of local bends without breaking the threadlike or ribbon-like element; in this way, the spring properties of the element 100 are retained and the element 100 obtains the necessary shape and functional characteristics in a quick and efficient manner.

Further, regarding the structure, as you can see, the element 100 has at least one (and preferably two) parts 14 for rotary mounting; moreover, these parts are made integrally in the filamentary or ribbon-like element and are designed to rotate the connection of the element 100 with the corresponding mounting pin.

It is advisable that the (imaginary) center of rotation defined by said mounting pin be made so that it is at a higher height than the abutment plane of the support side 3a of the base part 3; thus, having this center of rotation in the “raised” position relative to the guide 1, when a load perpendicular to the plane of the load on the guide 1 appears, the element 100 reacts in such a way that it tends to return to its equilibrium position, and thus the intrinsic reliability of the entire system consisting of nodes, including the guide 1 + intermediate connecting element 100 + mounting plate (on which the mounting pin is placed).

Referring to the drawings, it can finally be noted that the element 100 may comprise at least one, and preferably two, elastic counter-segments 15; these segments are also made integrally in the threadlike or ribbon-like element and are designed to counteract the possible rotation of the element 100 around the mounting pin.

The present invention provides several important advantages.

First of all, due to the given constructive configuration of the rail, one can get the advantage of shifting the so-called "stress center", the result of which is an increase in structural efficiency and a decrease in mass.

In addition, the steps of forming a new and original cross section of a real elevator guide can be carried out with high accuracy in molding, high production speed and maintaining a consistently high level of quality for various elements produced.

On the other hand, with regard to the installation of this guide for elevators, it should be noted that the possibility of using an intermediate fastener described above (and further stated), allows for faster and easier installation, which mainly reduces the cost and time of installation of the elevator installation.

Referring finally to the intermediate connecting element 100, it should be noted that in addition to the advantages already mentioned in terms of structural simplicity, intrinsic reliability and easy and quick installation, it also provides a new set of functional stops for the rail, which is held in place by at least two perpendicular to each other in the laying / installation plane, and is also kept from possible actions of "slipping".

In other words, the new connection between the element 100, the guide 1 and the mounting plate (informally referred to as the “butt plate”) not only reduces installation time, but also allows you to hold the guide in place in a simpler way, making installation and alignment easier.

In addition, using the characteristics of the particular type of connection created between the element 100 according to the invention and the guide (which may be of the type previously described and further described as well as a guide of a known type), the installation can be further simplified; as a rule, fixing in an alternating way, from one side of the guide to the other (i.e. starting from the element on the right, then fixing the element on the left and so on), which eliminates the need for the so-called “pre-tightening” of the screws (on the other hand, “final tightening” operation is not needed).

It should also be noted that this intermediate connecting element is not subject to the vibrational state and thermal cycles that may occur during operation of the elevator installation; and even in the case of a seismic phenomenon, the “guide + connecting element” system provides absorption of structural overloads due to the elastic cushioning action of the connecting element itself.

In addition, this system is in any case free from the likelihood of spontaneous or uncontrolled disconnection, since the guide can be removed from the connecting element only through the directed action of the operator; and moreover, due to the described construction, the possible intervention of the operator always leads to an increase in the holding reaction, which, in case of interruption or failure of the intervention, should return the connecting element to the initial equilibrium state (and, therefore, to the "holding" state of the guide).

Claims (12)

1. Guide for elevators or elevators, containing the main body (2), elongated along the main axis (2A) and including, in cross section:
- a base part (3) having a supporting side (3a) intended to adjoin the wall, in accordance with the installation conditions of the guide (1), and a direction-defining side (3b) opposite the said supporting side (3a) and forming, together with the latter, a variable thickness of said base portion (3);
- two boundary ribs (4) located on mutually opposite side faces of the base part (3);
- a central protrusion (5) protruding from said direction-determining side (3b) and having a proximal base (5a) connected to the base part (3), and a remote bulge (5b) connected to the proximal base (5a);
at least one mass redistribution portion (6) formed in the base part (3) and intended to facilitate the base part (3) in its intermediate part located between the central protrusion (5) and at least one boundary rib (4) and also intended to weight the base part in its end part located near at least one boundary rib (4), said mass redistribution section (6) comprising a lightening recess (6a) made in said direction-defining side (3b); and
- at least one connecting portion (7) located between the facilitating recess (6a) and said proximal base (5a) and having a peak-shaped configuration and / or a pointed configuration in cross section relative to the main axis (2a);
moreover, the guide has dimensions in cross section in the following ranges:
- total height ranging from 60 to 80 mm; and / or
- the width of the base part (3) in the range from 60 to 95 mm; and / or
- the width of the removed thickening (5b) in the range from 7 to 18 mm; and / or
- the height of the removed thickening (5b) in the range from 30 to 45 mm; and / or
- the height of at least one boundary rib (4) in the range from 6 to 12 mm; and / or
- the height of the center of gravity of the cross section relative to the base part (3) in the range from 18 to 30 mm; and / or
- cross-sectional area in the range from 8 to 20 cm ² . 2. The guide according to claim 1, additionally containing two sections (6) of the redistribution of mass located on mutually opposite sides relative to the central protrusion (5). 3. A guide according to claim 1, in which at least one, and preferably both, sections (6) of the mass redistribution contain a facilitating recess (6a) made in the direction-defining side (3b) and a local thickening (6b) near the boundary rib ( four). 4. A guide according to claim 3, wherein said facilitating recess (6a) and / or local thickening (6b) form respectively an intermediate part and an end part of a base part (3) having a constant cross-sectional thickness relative to said main axis (2a). 5. The guide according to claim 1, having dimensions in cross section in the following ranges:
- total height in the range from 65 to 75 mm; and / or
- the width of the base part (3) in the range from 70 to 90 mm; and / or
- the width of the removed thickening (5b) in the range from 8 to 16 mm; and / or
- the height of the removed thickening (5b) in the range from 34 to 42 mm; and / or
- the height of at least one boundary rib (4) in the range from 7 to 10 mm; and / or
- the height of the center of gravity of the cross section relative to the base part (3) in the range from 20.4 to 26.1 mm; and / or
- the cross-sectional area in the range from 9.51 to 17.25 cm ² . 6. A method of manufacturing a guide for elevators or elevators, comprising the steps of:
- preforming the preform by means of a predetermined number of coarse processing steps, wherein said preform is profiled at least along its main axis (2a); and
- finishing the workpiece by means of a given number of finishing stages following the said stages of rough processing, while the workpiece takes the form, in cross section, transverse to the main axis (2a), having at least one base part (3), the supporting side (3a), intended for adjoining the wall, the direction-defining side (3b) opposite to the said supporting side (3a), two boundary ribs (4) and a central protrusion (5), made in accordance with any of paragraphs. 1-5,
- performing redistribution of mass at least in the base part (3), intended to facilitate the base part (3) in its intermediate part between the central protrusion (5) and at least one boundary rib (4), as well as to weight the base part ( 3) in its terminal part, localized near at least one boundary rib (4),
characterized in that said mass redistribution execution step comprises a sub-step of facilitating recessing (6a) in said direction-determining side (3b) of said base part (3) forming a guide at least according to claim 1. 7. The method of claim 6, wherein said steps of preforming the preform, fine-tuning the preform, and performing weight redistribution are performed by profiling and / or drawing and / or gouging and / or rolling and / or hot rolling. 8. An intermediate bonding element for mounting between a guide for elevators or elevators according to claim 1 and a wall, comprising:
- the connecting part (10) intended for connection with the wall; and
- the active part (11) connected to the aforementioned connecting part (10) and made with the possibility of activation on the guide for elevators of the type described in clause 1 and / or manufactured by the method according to clause 6,
characterized in that it further comprises elastic clamping means made integrally in the connecting part (10) and / or the active part (11) and configured to hold the guide (1) for the elevators in place by means of elastic forces and / or by direct mechanical interaction . 9. The element according to claim 8, in which the connecting part (10) and the active part (11) are made without breaking by bending and / or profiling a threadlike or ribbon-like element, preferably from a metal material, while maintaining elastic properties. 10. The element according to claim 8, in which the intermediate connecting element (100) further comprises:
- at least one docking socket (12), made integrally in the aforementioned filiform or ribbon-like element and designed to introduce a release tool; and / or
- a predetermined number of blocking extensions (13), made integrally in the aforementioned filiform or ribbon-like element and intended to abut at least one boundary rib (4)
and / or said facilitating recess (6a) and / or said local thickening (6b),
wherein said docking socket (12) and said blocking extensions (13) consist of local bends without breaking the threadlike or ribbon-like element. 11. The element according to claim 8, containing at least one, and preferably two segments (14) for rotary mounting, and these segments are made integrally in a thread-like or ribbon-like element and configured to rotate the connection of the intermediate element (100) with the corresponding mounting pin, moreover, said mounting pin forming a center of rotation for the intermediate element (100) is located at a higher height than the abutment plane of the supporting side (3a) of the base part (3). 12. The element according to claim 8, containing at least one, and preferably two elastic counter-segments (15), made integrally in the threadlike or ribbon-like element and configured to counteract the possible rotation of the intermediate element (100) around said mounting pin.

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